TWI483759B - Manufacturing method of high strength golf head with thin face - Google Patents

Description

Method for manufacturing high-strength golf iron head with thin hitting panel

The present invention relates to a method of manufacturing a golf club head, and more particularly to a method of manufacturing a high-strength golf iron head having a thin hitting panel that can produce an integrally formed high-strength golf iron head.

Generally speaking, golf clubs can be divided into three categories: wood poles, irons and putters. Early wood heads and iron heads are made of stainless steel or carbon steel, which is used to improve the functionality of golf club heads. A variety of new steel casting materials have been developed and used to make golf club heads; for example, steel alloys containing cobalt, molybdenum or titanium generally have "high strength (tensile strength greater than 250 ksi)" characteristics. It is especially suitable for making golf iron heads.

The current golf iron heads are mostly in the atmosphere, and the high-frequency induction furnace (High Frequency Induction Furnace) is used to rapidly melt the cast material, and the refining steps such as slagging and degassing remove the impurities in the molten metal. It is cast with gas and static gravity casting.

However, the cast iron of the golf iron head often contains active metals (such as manganese, aluminum, lanthanum, cobalt, molybdenum, titanium, etc.) which are easily reacted with oxygen in the atmosphere, so that it is easy to smelt the cast material and generate oxygen. The violent oxidation reaction not only causes the difficulty of melting, but also reacts with air to cause oxidative cracking during casting, resulting in appearance defects such as sesame spots and black beans on the golf iron head casting after casting, even by reaction. The gas forms a large number of casting defects such as slag holes or reaction pores on the golf iron head casting, so that the tensile strength of the golf iron head casting is strong. The degree is affected, thereby limiting the thickness of the hitting panel of the golf iron head.

That is, in order to ensure that the hitting panel of the golf iron head can reach a certain tensile strength standard, to withstand the preset strength and the number of shots without damage, the currently formed golf iron head has the thinnest hitting panel. The thickness is still thick; Table 1 is a golf iron head made of various materials made by gravity casting in the atmosphere. The tensile strength and the thinnest thickness of the hitting panel are listed, and the "thinest thickness" is set as the hit. The ball panel can withstand a bombardment strength of 50 m/s, and the 3,000 shots are destroyed without destroying the thinnest thickness of the hitting panel (excluding the trench depth).

It can be seen from Table 1 that the tensile strength of the hitting panel of the golf iron head of various materials has a high degree of correlation with the thinnest thickness to achieve the same shelling condition; that is, the higher the tensile strength of the hitting panel, the most The thinner thickness can be smaller. In addition, under the above-mentioned shelling conditions, the thinner thickness of the currently formed golf iron head's ball striking panel without the depth of the trench is about 2.59 mm on average, which is for hitting balls with higher strength (above 250 ksi). The thickness of the panel, which does not contain the depth of the trench, must also be at least 2.0 mm, so the current golf iron head has a bottleneck that is difficult to reduce the overall weight.

On the other hand, the severe oxidation reaction also causes the fluidity of the molten metal in the shell mold to decrease, which is liable to cause a decrease in the molding yield of the golf iron head casting due to insufficient casting, or a problem of cold lock (Cold Shut). The formation of a gap in the golf iron head casting also affects the tensile strength of the golf iron head casting.

For the above reasons, the manufacturing method of the conventional golf iron head has been improved.

The object of the present invention is to provide a method for manufacturing a high-strength golf iron head with a thin ball striking panel, which can reduce the chemical reaction of the casting material with the atmosphere during the smelting process, thereby improving the tensile strength of the casting and making the golf iron head The hitting panel is thinned.

A second object of the present invention is to provide a method for manufacturing a high-strength golf iron head having a thin hitting panel, which can improve the forming yield and quality of the casting.

In order to achieve the foregoing objectives, the technical content of the present invention includes: a method for manufacturing a high-strength golf iron head having a thin hitting panel, comprising: positioning a shell mold on a rotating platform, the shell mold comprising a turn portion and a cavity portion, and the rotating platform is coupled to an axially rotatable rotating shaft; at least one metal ingot is placed on the crotch portion of the shell mold, and the ingot is heated and melted in a vacuum environment Forming a molten metal; driving the rotating shaft to rotate the rotating platform to cause molten metal to flow into the cavity portion of the shell mold Stopping the rotating shaft slowly, and removing the cast shell mold; after the molten metal liquid is cooled and solidified, the shell mold is broken to obtain a casting, and the casting includes a casting portion; the casting portion is removed from the casting portion Separating the cast to obtain at least one golf iron head; heat-treating the golf iron head to make the hitting panel of the golf iron head have a tensile strength of 280-340 ksi and an elongation of 4%-20 %, and the minimum thickness of the hitting panel of the golf iron head without the depth of the trench is 1.4 to 1.8 mm; wherein the molding step of the shell mold comprises: preparing a wax embryo, the wax embryo comprising an embryo and a casting embryo, the circumferential surface of the embryo is provided with a first connecting portion, the casting embryo is provided with a second connecting portion, and the first connecting portion and the second connecting portion are oppositely connected to each other; The surface forms a coating layer; the wax embryo and the coating layer are heated to melt the wax; the dewaxed coating layer is sintered at a high temperature to form the shell mold, and the shell mold is integrally connected The crotch and the cavity.

Wherein, the number of the metal ingots may be a single one, and the metal ingot is a high-strength steel alloy, and the composition combination of the metal ingot is consistent with the composition combination of the high-strength golf iron head to be made.

Alternatively, the number of the metal ingots may be several, and the composition of the molten metal after the molten metal ingots is in accordance with the composition of the components of the high-strength golf iron head to be produced.

Wherein, the surface layer material of the shell mold may be zirconium silicate, cerium oxide, diazepam or alumina.

The back layer material of the shell mold may be a mullite mixture, the content of the aluminum oxide is 45% to 60%, and the content of the cerium oxide is 55% to 40%.

Wherein, the back layer material of the shell mold may be a cerium oxide mixture, and the content of cerium oxide is more than 95%.

Accordingly, the method for manufacturing the high-strength golf iron head with the thin hitting panel of the present invention can reduce the chemical reaction of the cast material with the atmosphere during the smelting process, thereby improving the tensile strength of the casting and making the golf iron head The batting panel is thinned and the casting is molded at the same time Yield and quality.

1‧‧‧vacuum furnace

11‧‧ ‧ room

12‧‧‧ Airway tube

13‧‧‧ openings

14‧‧‧ Cover

2‧‧‧ shaft

21‧‧‧ body

22‧‧‧Turning

23‧‧‧Abutment

3‧‧‧Rotating platform

31‧‧‧Axis joint

311‧‧‧Perforation

32‧‧‧ Positioning Department

32a‧‧‧坩埚Location Department

32b‧‧‧Acupoint Positioning Department

321‧‧‧With holes

322‧‧‧ 容容

4‧‧‧Shell mold

41‧‧‧坩埚

411‧‧‧ accommodating space

412‧‧‧First connecting tube

413‧‧‧ ring lip

42‧‧‧Move

421‧‧‧ cavity

422‧‧‧Second connection tube

5‧‧‧heater

6‧‧‧Wax embryo

61‧‧‧坩埚 embryo

611‧‧‧First connection

62‧‧‧ casting embryo

621‧‧‧Second connection

7‧‧‧Cladding

8‧‧‧ collar

M‧‧ motor

B‧‧‧ bearing

L‧‧‧ Lifting controller

P‧‧‧metal ingots

N‧‧‧metal liquid

Fig. 1 is a schematic view showing the structure of a vacuum centrifugal casting apparatus used in conjunction with the present invention.

Fig. 2 is a partial perspective exploded view of the vacuum centrifugal casting apparatus used in conjunction with the present invention.

Figure 3: Schematic diagram (I) of the implementation of the present invention.

Fig. 4 is a schematic view showing the molding process of the shell mold of the vacuum centrifugal casting apparatus used in the present invention.

Figure 5: Schematic diagram (2) of the implementation of the present invention.

Figure 6: Schematic diagram (3) of the implementation of the present invention.

Figure 7 is a schematic view showing the structure of another vacuum centrifugal casting apparatus used in conjunction with the present invention.

The above and other objects, features and advantages of the present invention will become more <RTIgt; A method of manufacturing a high-strength golf iron head having a thin hitting panel of the present invention is used in combination with a vacuum centrifugal casting apparatus. Wherein, the vacuum centrifugal casting device comprises a vacuum furnace 1, a rotating shaft 2, a rotating platform 3, a shell mold 4 and a heater 5; the rotating shaft 2, the rotating platform 3, the shell mold 4 and the heater 5 are all disposed at In the vacuum furnace 1, the rotating platform 3 is coupled to the rotating shaft 2 for synchronous rotation with the rotating shaft 2. The shell mold 4 is positioned and placed on the rotating platform 3, and the heater 5 is used to heat the shell mold 4.

More specifically, the inside of the vacuum furnace 1 has a chamber 11 , and the vacuum furnace 1 can be provided with an air duct 12 , the air tube 12 is connected to the chamber 11 , and a vacuum controller (not shown) The chamber 11 can be evacuated through the air duct 12 according to a set value to control the degree of vacuum of the chamber 11. In addition, the vacuum furnace 1 can also be provided with an opening 13 for the user to The chamber 11 is inserted or removed, and a cover 14 is provided to open and close the opening 13.

Referring to Figures 1 and 2, the shaft 2 is axially rotatably disposed in the chamber 11 of the vacuum furnace 1; in the present embodiment, the shaft 2 is connectable to the output of a motor M. The motor M drives the rotation. Moreover, the motor M can be selectively disposed outside the vacuum furnace 1, and one end of the rotating shaft 2 extends out of the vacuum furnace 1 to connect the motor M; the rotating shaft 2 can be placed in a bearing B, and the bearing B can be The connection is positioned in the vacuum furnace 1 to assist in improving the rotational stability of the rotating shaft 2, and preventing the yaw from occurring when the rotating shaft 2 rotates.

In addition, the portion of the rotating shaft 2 located in the chamber 11 can be divided into a body 21 and a rotation preventing portion 22, and the radial cross-sectional shape of the body 21 and the rotation preventing portion 22 are different to form an offset at the boundary between the two. a portion 23 for the rotating platform 3 to be coupled to the abutting portion 22 and abutting against the abutting portion 23, so that the rotating platform 3 can rotate synchronously with the rotating shaft 2; in the embodiment, the body 21 The radial section may be in the form of a circle. The rotation stop 22 may be disposed at the end of the rotating shaft 2, and the radial section of the rotation stop 22 is in a non-circular shape for the sleeve 3 to be coupled. The rotation stop portion 22 abuts against the abutment portion 23.

Referring to FIGS. 2 and 3, the rotating platform 3 is a carrier for positioning the shell mold 4, and the rotating platform 3 is provided with a connecting portion 31 and a positioning portion 32; in this embodiment, The shaft portion 31 can be provided with a through hole 311. The radial cross-sectional shape of the through hole 311 is matched with the radial cross-sectional shape of the rotation preventing portion 22 of the rotating shaft 2 for the rotating platform 3 to pass through the shaft portion. The through hole 311 of the sleeve 31 is connected to the rotation preventing portion 22 of the rotating shaft 2. The positioning portion 32 of the rotating platform 3 can be roughly divided into a positioning portion 32a and a cavity positioning portion 32b. The positioning portion 32a is located between the shaft portion 31 and the cavity positioning portion 32b, and the shaft is connected. The portion 31, the positioning portion 32a and the cavity positioning portion 32b are arranged according to the radial extension of the rotating shaft 2; further, the positioning portion 32a can be provided with a through hole 321 for a part of the shell mold 4 to extend through The cavity positioning portion 32b can be provided with a cavity 322 for accommodating another part of the shell mold 4.

Referring to Figures 2 and 3, the shell mold 4 has a connecting portion 41 and a cavity portion 42, the crotch portion 41 of the shell mold 4 can be positioned and placed on the locating portion 32a of the rotating platform 3, and the cavity portion 42 of the shell mold 4 can be positioned to position the cavity of the rotating platform 3 The portion 32b causes the crotch portion 41 of the shell mold 4 to be closer to the shaft portion 31 of the rotary table 3 than the cavity portion 42.

The sill portion 41 can be formed in a cup shape to form an accommodating space 411 therein. The accommodating space 411 can be used to receive a molten metal ingot, and the ring portion 41 has a first circumferential surface. The connecting tube 412 is connected to the accommodating space 411. The cavity portion 42 is a portion for forming a golf iron head. The shape of the cavity portion 42 is not particularly limited. The cavity portion 42 has at least one cavity 421 therein. The shape and shape of the cavity 421 The cast iron head to be cast is matched; the cavity portion 42 is further provided with a second connecting pipe 422, the second connecting pipe 422 is connected to the cavity 421, and the crotch portion 41 and the cavity portion 42 are A connecting tube 412 and a second connecting tube 422 are opposite to each other, so that the accommodating space 411 is in communication with the cavity 421.

Referring to FIG. 4, in the embodiment, the crotch portion 41 of the shell mold 4 and the cavity portion 42 may be integrally connected. The molding process of the shell mold 4 is: preparing a wax embryo 6, the wax embryo 6 includes an embryo 61 and a casting embryo 62. The circumferential surface of the embryo 61 is provided with a first connecting portion 611, and the casting embryo 62 is provided with a second connecting portion 621, the embryo 61 and the casting The embryo 62 is integrally connected to each other by the first connecting portion 611 and the second connecting portion 621. The wax blank 6 is subjected to a process such as dipping, sanding or grit, and a coating layer 7 is formed on the surface of the wax blank 6. The wax embryo 6 and the coating layer 7 are heated to melt the wax; for example, the wax embryo 6 and the coating layer 7 may be placed together in a steam autoclave to melt the wax embryo 6 to The coating layer 7 is discharged. The dewaxed cladding layer 7 is sintered at a high temperature to form the shell mold 4, and the shell mold 4 has an integrally joined crotch portion 41 and a cavity portion 42. Wherein, the surface layer material of the shell mold 4 may be selected from refractory materials such as zirconium silicate, cerium oxide, diazepam or alumina, and the back layer material of the shell mold 4 may be selected from mullite (3Al ₂ O ₃ -2SiO). ₂ ) or cerium oxide as a refractory material; further, when the back layer material is a mixture of mullite, the content of the aluminum oxide is preferably 45% to 60%, and the content of cerium oxide is preferably 55%. 40%; when the back layer material is a mixture of cerium oxide, the content of cerium oxide is preferably more than 95%.

Referring to FIGS. 1 and 3 again, the heater 5 is disposed in the chamber 11 of the vacuum furnace 1 for heating the crotch portion 41 of the shell mold 4. In this embodiment, the heater 5 can be selected as a high-frequency coil, and the heater 5 is moved by the lift controller L in the chamber 11; when the crotch portion 41 of the shell mold 4 is to be heated, The heater 5 can be driven up to a predetermined position to surround the outer circumference of the crotch portion 41, and the heater 5 is activated to heat the crotch portion 41. After the heating is completed, the heater 5 can be heated. The lift controller L is driven to descend so that the heater 5 no longer surrounds the outer circumference of the jaw portion 41 so as not to interfere with the rotation of the shell mold 4 with the rotating platform 3 and the rotating shaft 2.

According to the foregoing structure, the present invention can implement a method of manufacturing a high-strength golf iron head having a thin ball striking panel, the manufacturing method generally comprising the following steps: refer to Figures 1 to 3 to position a shell mold 4 On a rotating platform 3, the rotating platform 3 is connected to an axially rotatable rotating shaft 2. More specifically, the rotating platform 3 can be disposed in a vacuum furnace 1 to control the degree of vacuum of the space in which the shell mold 4 is located. In addition, the shell mold 4 includes a connecting portion 41 and a cavity portion. The shell mold 4 can be inserted into the through hole 321 of the rotating platform 3 by the dam portion 41, and the first connecting tube 412 of the dam portion 41 abuts against the rotating platform 3, and the shell mold 4 The cavity portion 42 can be placed on the cavity 322 of the rotating platform 3, so that the shell mold 4 can be stably fixed at a preset position on the rotating platform 3. And, at least one metal ingot P is placed in the crotch portion 41 of the shell mold 4; when the number of the metal ingots P is selected to be a single one, the metal ingot P is a high-strength steel alloy, and the metal ingot P The composition of the components is consistent with the composition of the components of the high-strength golf iron head to be made; when the number of the metal ingots P is several, the composition of the molten metal after the melting of the plurality of metal ingots P is desired to be made. The composition of the high-strength golf iron head is consistent.

Referring to Figures 1 and 5, the ingot P is heated and melted into a molten metal N in a vacuum environment. More specifically, after the housing mold 4 is positioned, the heater 5 can be driven up to a predetermined position to surround the outer circumference of the jaw portion 41; meanwhile, the air duct 12 of the vacuum furnace 1 can be directed The chamber 11 is evacuated to control the degree of vacuum of the chamber 11. After the vacuum degree reaches a preset value (for example, the degree of vacuum is less than 0.3 mbar), the heater 5 can be activated to heat the crotch portion 41 of the shell mold 4 to melt the metal ingot P in the crotch portion 41. The metal liquid N; wherein, when the heater 5 is actuated, the frequency of the power supply may be, for example, 4 kHz to 30 kHz, and the power is 5 kW to 100 kW. After the metal ingot P is melted into the molten metal N, the heater 5 stops acting and is rapidly driven down so that the heater 5 no longer surrounds the outer circumference of the weir portion 41.

Referring to Figures 1 and 6, the rotating shaft 2 is driven to rotate the rotating platform 3 to cause molten molten metal N to flow into the cavity portion 42 of the shell mold 4. More specifically, the shaft 2 can be driven by the motor M to produce an axial rotation having a rotational speed of about 200 rpm to 700 rpm, which can be adjusted according to the thickness of the casting (i.e., the size of the cavity 421); When the platform 3 is rotated and the shaft 2 is rotated as an axis, during the rotation, the molten metal N can be subjected to centrifugal force along the inner wall surface of the crotch portion 41 of the shell mold 4, passing through the first shell mold 4 The connection pipe 412 and the second connection pipe 422 flow into the cavity portion 42 to perform a casting operation, and further fill the cavity 421.

After the casting is completed, the rotating shaft 2 can be stopped slowly, and the shell mold 4 is removed from the rotating platform 3; after the molten metal liquid N is cooled and solidified, the shell mold 4 is broken to obtain a casting, and the casting is performed. The article includes a casting portion; the casting portion is separated from the casting (for example, by cutting with a cutter or by breaking with a vibration) to obtain at least one golf iron head. The golf iron head is further heat treated so that the impact strength of the golf club head is 280-340 ksi, the elongation is 4%-20%, and the impact strength is 50 m/s, 3000 times. The number of shots of the golf iron head does not include the minimum thickness of the trench depth of about 1.4 to 1.8 mm, which helps to reduce the overall weight of the golf iron head and reduce its weight. The hitting panel; wherein the hitting panel of the golf iron head may be in the form of equal thickness or unequal thickness, and the invention is not limited thereto.

Therefore, the method for manufacturing the high-strength golf iron head with the thin hitting panel of the present invention can be cast in a near-vacuum environment to reduce the chemical reaction of the cast material with the atmosphere during the smelting process, so that the metal ingot P It is easier to smoothly and uniformly melt, thereby avoiding the situation in which the molten metal N reacts with air to cause oxidative cracking during the flow from the crotch portion 41 of the shell mold 4 into the cavity portion 42, so that the golf iron head is made. It is not easy to produce appearance defects such as sesame spots and black beans on the casting, and casting defects such as slag holes or reaction pores formed by the reaction gas are not easily generated to improve the tensile strength of the golf iron head casting.

On the other hand, reducing the chemical reaction between the molten metal N and the atmosphere can also improve the fluidity of the molten metal N in the shell mold 4, and the present invention can use the centrifugal force to transfer the molten metal N before the molten molten metal N is solidified again. The hole 421 filled in the shell mold 4 is surely watered, not only to prevent a part of the molten metal N from solidifying in the crotch portion 41 to form a shell, but also to waste the cast material, and to ensure that the molten metal N flows into the cavity portion 42 of the shell mold 4. The cavity portion 42 can be fully filled to improve the molding yield of the golf iron head casting, and reduce the chance of forming a gap in the golf iron head casting by the cold separation, so as to improve the resistance of the golf iron head casting. Pull strength.

Therefore, the present invention can produce a golf iron head having high strength characteristics, thereby thinning the hitting panel of the high-strength golf iron head, so that the high-strength golf iron head has only the thinnest thickness. The thin ball striking panel of about 1.4~1.8mm can still ensure the high strength and good elongation of the ball striking panel to improve the hitting resistance of the ball striking panel, so that the high-strength golf iron head can not only have If the high rebound coefficient and other good hitting performance, it can extend its service life.

In addition, referring to FIG. 7 , in another embodiment, the manufacturing method of the high-strength golf iron head with the thin ball striking panel of the present invention can also be used in combination with the shell mold 4 having a plurality of cavity 421, once and for all. Several high-strength golf iron heads are cast to increase manufacturing efficiency.

In summary, the method for manufacturing the high-strength golf iron head with the thin hitting panel of the present invention can reduce the chemical reaction of the cast material with the atmosphere during the smelting process, thereby improving the tensile strength of the casting and making the golf iron head The hitting panel is thinned.

The invention relates to a method for manufacturing a high-strength golf iron head with a thin hitting panel, which improves the forming yield and quality of the casting.

While the invention has been described in connection with the preferred embodiments described above, it is not intended to limit the scope of the invention. The technical scope of the invention is protected, and therefore the scope of the invention is defined by the scope of the appended claims.

2‧‧‧ shaft

21‧‧‧ body

22‧‧‧Turning

23‧‧‧Abutment

31‧‧‧Axis joint

311‧‧‧Perforation

32‧‧‧ Positioning Department

32a‧‧‧坩埚Location Department

32b‧‧‧Acupoint Positioning Department

321‧‧‧With holes

322‧‧‧ 容容

4‧‧‧Shell mold

41‧‧‧坩埚

411‧‧‧ accommodating space

412‧‧‧First connecting tube

42‧‧‧Move

421‧‧‧ cavity

422‧‧‧Second connection tube

5‧‧‧heater

N‧‧‧metal liquid

Claims (6)

A method for manufacturing a high-strength golf iron head with a thin hitting panel, comprising: positioning a shell mold on a rotating platform, the shell mold comprising a connecting portion and a cavity portion, and the rotating platform Connected to an axially rotatable rotating shaft; at least one metal ingot is placed on the crotch portion of the shell mold, and the metal ingot is heated and melted into a molten metal under a vacuum environment; the rotating shaft is driven to rotate the rotating platform to rotate The molten metal liquid flows into the cavity portion of the shell mold; the rotating shaft is stopped slowly, and the cast shell mold is removed; after the molten metal liquid is cooled and solidified, the shell mold is broken to obtain a casting, The casting includes a casting portion; the casting portion is separated from the casting to obtain at least one golf iron head; the golf iron head is heat treated to make the impact strength of the golf club head hitting panel The 280~340ksi, the elongation is 4%~20%, and the minimum thickness of the hitting panel of the golf iron head without the depth of the trench is 1.4~1.8mm; wherein the forming step of the shell mold comprises: preparing a wax embryo The wax embryo comprises an embryo and a casting embryo, and the circumferential surface of the embryo is provided with a first connecting portion, the casting embryo is provided with a second connecting portion, the first connecting portion and the second connecting portion Coupling integrally; forming a coating layer on the surface of the wax embryo; heating the wax embryo and the coating layer to melt the wax; forming the decarburized coating layer at a high temperature to form the shell mold And the shell mold has an integrally connected crotch portion and cavity portion. The method for manufacturing a high-strength golf iron head having a thin hitting panel according to the first aspect of the invention, wherein the metal ingot is a single one, the metal ingot is a high-strength steel alloy, and the metal The composition of the components of the ingot is consistent with the composition of the components of the high strength golf iron head to be made. The method for manufacturing a high-strength golf iron head having a thin ball striking panel according to claim 1, wherein the number of the metal ingots is several, and the composition of the molten metal after melting the plurality of metal ingots The composition of the high-strength golf iron head to be made is consistent. The method for manufacturing a high-strength golf iron head having a thin ball striking panel according to any one of claims 1 to 3, wherein the surface layer material of the shell mold is zirconium silicate, cerium oxide, and diazepam. Zirconia or alumina. The method for manufacturing a high-strength golf iron head having a thin ball striking panel according to any one of claims 1 to 3, wherein the back layer material of the shell mold is a mullite mixture, and the trioxide is used. The content of aluminum is 45% to 60%, and the content of cerium oxide is 55% to 40%. The method for manufacturing a high-strength golf iron head having a thin ball striking panel according to any one of claims 1 to 3, wherein the back layer material of the shell mold is a cerium oxide mixture, which is oxidized. The content of strontium is over 95%.